Aqueous Chemical Co-Precipitation of Iron Oxide Magnetic ...
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Article
Volume 10, Issue 2, 2021, 2215 - 2239
https://doi.org/10.33263/LIANBS102.22152239
Aqueous Chemical Co-Precipitation of Iron Oxide
Magnetic Nanoparticles for Use in Agricultural
Technologies
Olga A. Shilova 1.2,* , Gayane Panova 3 , Anton Nikolaev 1 , Anastasia Kovalenko 1 , Alexandr
Sinelnikov 4, Gennady Kopitsa 5 , Alexandr Baranchikov 6 , Olga Udalova 3 , Anna Artemyeva 7 ,
Dmitry Kornyuchin 7 , Lyudmila Anikina 3 , Anna Zhuravleva 3 , Yuriy Khomyakov 3 , Vitalyi
Vertebnyi 3 , Victoria Dubovitskaya 3 , Tamara Khamova 1
1 Institute of Silicate Chemistry of Russian Academy of Sciences, St. Petersburg, Russia 2 Saint-Petersburg State Electrotechnical University “LETI”, Saint-Petersburg, Russia 3 Agrophysical Research Institute, St. Petersburg, Russia 4 Voronezh State University, Voronezh, Russia 5 Petersburg Nuclear Physical Institute named by B.P. Konstantinov of National Research Centre “Kurchatov Institute”,
Gatchina, Leningrad Region, Russia 6 Kurnakov Institute of General and Inorganic Chemistry of the Russian Academy of Sciences, Moscow, Russia
* Correspondence: [email protected];
Scopus Author ID 6701888918
Received: 1.10.2020; Revised: 21.10.2020; Accepted: 22.10.2020; Published: 25.10.2020
Abstract: Magnetic nanoparticles of iron oxides were obtained by precipitation from aqueous solutions
of iron chlorides (Fe2+/Fe3+). It is shown that, depending on the use of various technological techniques
in their synthesis (ultrasound, bubbling with argon, heating, the addition of oleic acid), nanoparticles 5-
40 nm in size, spherical or plate-like, with a specific surface area of 52-92 m2/g, are formed
corresponding to maghemite or solid solutions of maghemite with magnetite. The latter, in particular,
are synthesized with a shell of oleic acid. Aqueous suspensions of nanoparticles (0.00001 to 100 mg/L)
were used for the pre-sowing treatment of seeds of spring barley, cabbage, and salad crops, as well as
for foliar treatment (0.001 to 1 mg/L) of vegetative cucumber and lettuce plants. It was found that these
nanoparticles do not possess fungicidal and bactericidal activity against pathogens (Xanthomonas
campestris pv. campestris (Pammel) Dowson) of cabbage vascular bacteriosis, barley dark brown spot,
and root rot (Cochliobolus sativus (S. Ito & Kurler ex.) Drechs. Dastur), but exhibit weak fungicidal
activity in certain concentrations, in particular, against the causative agents of blackleg in white
cabbage. Presowing seed treatment, in general, has a positive effect on germination and morphometric
parameters of different plants. These parameters significantly depend on the concentration of
nanoparticles in suspensions, their phase composition, and the presence or absence of an inert shell on
the surface. Foliar treatments of cucumber and lettuce seedlings with suspensions of synthesized
nanoparticles improved the morphometric and biochemical parameters of plants, which together
provide a tendency to increase their productivity, which is more pronounced at a nanoparticle
concentration of 0.01 mg/L. In the future, it is possible to further enhance the phytoprotective effect of
iron oxide nanoparticles, which will reduce the dose load of persistent agrochemicals and pesticides on
the environment.
Keywords: nanoparticles; magnetite; maghemite; precipitation; pre-sowing treatment; foliat
treatment; morphometric parameters.
© 2020 by the authors. This article is an open-access article distributed under the terms and conditions of the Creative
Commons Attribution (CC BY) license (https://creativecommons.org/licenses/by/4.0/).
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1. Introduction
Using synthetic nanoparticles in agriculture as bioactive stimulators and fertilizers are
one of the prospective fields of research and therefore attracts a lot of attention from scientists
[1]. The positive influence of the nanoparticles on the plants includes photocatalytic activity,
an increase of the chlorophyll content, germination, and growth stimulation [2-8]. There is
evidence that nanoparticles can suppress plants in different ways: slowed growth, oxygen
stress, impaired photosynthesis, water transport disturbance, increasing of the sensibility to the
natural toxins [9-11]. But the researchers point out that nanoparticles influence plants via
several mechanisms at once, and the behavior of the nanoparticles in the environment itself is
regulated by the complicated principles, so the interaction between a specific plant and specific
nanoparticles should be studied in every single case [12].
Iron plays an important role in the plant metabolism: it increases growth rate, length of
leaves, chlorophyll content; it decreases the content of the hydrogen peroxide and therefore
decreases lipids oxidation [3]. Researchers state that although iron can be used as the fertilizer
in the form of nanoparticles of metallic Fe [6, 13-14], still, the FexOy oxides are the main usable
form of it [3, 9, 12, 14-17]. Particularly, one of the most used forms of iron oxide is the
maghemite – magnetic modification γ-Fe2O3.
It is worth noting that maghemite nanopowders can be used for the solution of multiple
problems: cleaning water from oil products [18, 19], utilizing maghemite in biomedical
applications as the contrasting agent for magnetic resonance imaging, hyperthermia, and drug
delivery [20-23]. These applications were developed earlier than agricultural ones, so the
possibility of using maghemite in agricultural technologies arose only recently [3, 6, 12, 14,
19, 24]. In this case, commercial end-products are often used, the composition and properties
of which are practically not described, as well as detailed data on products based on these
nanoparticles are not provided. Until now, there are conflicting opinions as to whether
magnetite or maghemite is better (safer and / or more efficient) to use in agricultural
technologies. One of the areas of research is the use of commercial or specially synthesized
nanoparticles of metal oxides, with functional layers (shells) created on their surface, which
make it possible to achieve better aggregate stability of the products on their basis, contain
nutrients for plants, improve biocompatibility with seeds or plants, reduce the toxic effect of
nanoparticles. Most authors are inclined to believe that it is necessary to study the effect of
nanoparticles on each plant species separately, taking into account the peculiarities of the
composition and structure of nanoparticles, studying their effect in a wide range of
concentrations used for treating seeds or plants.
The aim of this work was to synthesize magnetic nanoparticles (maghemite and / or
magnetite) to study their physicochemical and biological properties for the development and
improvement of technological methods for pre-sowing and foliar treatment of seeds and
vegetative plants. To achieve this goal, it was necessary to solve the following tasks:
- to synthesize and characterize magnetic nanoparticles of maghemite and / or
magnetite, differing in a number of basic characteristics: phase composition, size, morphology,
texture, and surface additives;
- to identify whether these nanoparticles have bactericidal and / or fungicidal properties,
whether they affect the resistance of plants to phytopathogens (for example, white cabbage);
- to reveal how the pre-sowing treatment of seeds with aqueous suspensions of the
obtained magnetic nanoparticles of iron oxides, depending on their composition, morphology,
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texture, concentration, affects germination and morphometric characteristics at the early stages
of development of the following important agricultural plants: spring barley; garden cress;
vegetable brassicas – white cabbage, cauliflower;
- to establish how the foliar treatment with aqueous suspensions of the obtained
magnetic nanoparticles affects the morphometric, physiological, and biochemical parameters
of vegetable crops using the example of cucumber and lettuce when growing plants under
controlled conditions of intensive light culture.
2. Materials and Methods
2.1 Synthesis of nanopowders
Based on the literature data [25-29] and our own experience [30-33], we synthesized
magnetic iron oxide nanopowders using three techniques of chemical deposition from aqueous
solutions of iron (II, III) salts.
1st technique. Aqueous solutions of iron chlorides FeCl2 and FeCl3 were mixed at room
temperature in a molar ratio FeCl2:FeCl3 = 1:2. Then an aqueous ammonia solution (12.5 wt.%)
was gradually added. According to the chemical reaction, magnetite should be obtained:
FeCl2 + 2FeCl3 + 8NH4OH = Fe3O4 + 8NH4Cl + 4H2O.
Since it is known about the successful use of maghemite for the treatment of plant
seedlings [3], we tried to oxidize magnetite and obtain precisely maghemite γ-Fe2O3
nanopowder:
4Fe3O4 + O2= 6Fe2O3
To promote the oxidation of magnetite to maghemite, the precipitation process was
carried out under the influence of ultrasound (240 W, 40 kHz) for 30 minutes. The powder
from the resulting suspension was extracted by magnetic separation using a neodymium
magnet, washed with water, and dried at 100 °C for 24 h. The synthesis scheme is shown in
Fig. 1 – 1st technique.
2nd technique. Aqueous solutions of iron chlorides FeCl2 and FeCl3 in the same molar
ratio were mixed with constant bubbling with argon. To intensify the process of nanopowder
deposition with an aqueous solution of ammonia (6.25 wt%), it was carried out under bubbling
with argon and at an elevated temperature of 60 °C. The powder from the resulting suspension
was extracted by magnetic separation using a neodymium magnet, washed with water, and
dried at 100 °C for 24 h. The synthesis scheme is shown in Fig. 1 – 2nd technique.
3rd technique. This technique was identical to the second one until the deposition of
the magnetic powder. Then, several operations were carried out to create a shell of oleic acid,
which was designed to mitigate the possible aggressive effect of magnetic iron oxide
nanoparticles on plants. For this, 1 ml of oleic acid was added to the freshly formed precipitate.
The mixture was vigorously stirred with a magnetic stirrer for 1 hour at a temperature
of 50 °C. The precipitate was recovered from the solution, not by magnetic separation, but by
decantation, then washed with water, and dried at 100 °C for 24 h. The synthesis scheme is
shown in Fig. 1 – 3rd technique.
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Figure 1. Three schemes of chemical synthesis of magnetic powders of iron oxides, differing by the methods of
co-precipitation process intensification.
2.2. Physicochemical methods for studying the phase composition, morphology, and texture of
nanopowders.
The phase composition and crystal structure of the powders were studied via powder
X-ray diffraction using a Bruker D8-Advance diffractometer (CuKα radiation, range 20 – 80°
2θ, step 0.0075°, exposure 7 s). The lattice parameters were calculated via the least-squares
method using the PDWin software package.
Since the powders turned out to be nanosized, FTIR spectroscopy was used to identify
the phase composition, which was also used to confirm the presence of oleic acid on the surface
of the powder nanoparticles. The measurements were performed using Infraspec FSM 2202
spectrometer. 1 mg of the sample was pressed with 200 mg of KBr in the tablet; measurement
was carried out in the wavelength range 400 – 4000 cm-1.
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The morphology of nanoparticles (size, shape, and degree of their aggregation) was
studied via scanning electron microscopy (SEM), which was carried out by means of a scanning
electron microscope with a field emission cathode (FE-SEM) ZeissMerlin, as well as using
high-resolution transmission electron microscopy (TEM) carried out by means of ZEISS Libra
120 transmission electron microscope at the Centre for Collective Use of Scientific Equipment
(CCUSE).
The measurements of the specific surface area of nanopowders were performed by low-
temperature nitrogen adsorption using QuantaChrome Nova 1200e analyzer. The samples were
degassed at 150 °C in a vacuum for 17 h prior to analysis. Based on the data obtained, the
specific surface area SBET was calculated for the samples using the Brunauer–Emmett–Teller
model (BET) and the seven points technique within the relative pressure range of P/P0 = 0.07
÷ 0.25 (where P0 is the saturation pressure). The calculation of the pore size distribution was
carried out on the basis of nitrogen isotherms using the Barrett-Joyner-Halenda (BJH)
technique.
2.3. The investigation of the aggregate stability of suspensions by colloidal techniques.
Since magnetic nanoparticles of iron oxides were supposed to be used for treating seeds
and plants in the form of aqueous suspensions, it was useful to assess their aggregate stability.
On the basis of iron oxide nanopowders, aqueous suspensions with a concentration of 0.1
mg/ml were prepared. To achieve better dispersion of nanoparticles in water, the powders were
exposed to ultrasound in an ultrasonic bath (240 W, 40 kHz) for 20 minutes. Freshly prepared
suspensions were muddy and highly concentrated. Therefore, they were left for 3 days to
achieve aggregate and sedimentation stability. Then, the aggregate stability of the supernatant
was measured by measuring the average hydrodynamic diameter of nanoparticles in an aqueous
suspension using the dynamic light scattering technique by means of NanoBrook 90 PlusZeta
device.
Due to the fact that some suspensions had larger mean hydrodynamic diameters than
the device allowed to measure, all suspensions were additionally diluted 10 times and, after
ultrasonic treatment for 20 minutes, were measured again. Subsequently, the suspensions, both
after the first and after the second dilution, were tested for aggregation stability after 1 week,
after 1 month, and after 4 months. Such an interest in the size of the aggregate in the water
suspensions is due to the importance of the water suspensions for the pre-sowing and foliar
treatment.
2.4. Biological, microbiological, and biochemical techniques for studying the properties of
magnetic nanoparticles of iron oxides and their effect on biological objects.
2.4.1. The evaluation of the bactericidal and fungicidal properties of magnetic iron oxide
nanoparticles.
The fungicidal and bactericidal properties of the investigated magnetic nanoparticles of
iron oxides were evaluated using two phytopathogens as test objects: a) the causative agent of
vascular bacteriosis of cabbage Xanthomonas campestris pv. campestris (Pammel) Dowson,
strain 5212; b) the causative agent of barley dark brown spotting and barley root rot, the
micromycete Cochliobolus sativus (S. Ito & Kurib.) Drechsler ex Dastur. The solutions of the
preparations were mixed in distilled water; for making the stock solutions, an Elmasonic S30H
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ultrasonic bath was used, into which a glass test tube with a substance and a solvent was
immersed for 30 minutes.
Evaluation of the magnetic iron oxide nanoparticles fungicidal activity was carried out
on pure cultures of phytopathogenic fungi by the dilution technique using Czapek’s nutrient
medium with lactose and urea as modified by Benken et al. [34]. The solution of the preparation
was added to the specified medium, poured into 12-well plates, 2 ml in each well, and cooled
to 45° C. After solidification, a spore suspension of a phytopathogenic fungus was applied to
the surface of the medium under sterile conditions at a concentration of 30 thousand spores per
1 ml of the medium or 50 μl per dish. After keeping Petri dishes with applied test objects in a
sterile cabinet for 1 day at a temperature of 25 °C, the germination of spores on the surface of
the medium was assessed in comparison with the control using an inverted microscope Biolam
P1.
The bactericidal activity of magnetic iron oxide nanoparticles was assessed according
to the technique of A.N. Ignatov [35]: a culture of phytopathogenic bacteria was incubated in
a modified liquid King B medium containing the preparation for 36 hours at 28 °C, followed
by plating on a solid nutrient medium of the same composition for testing the viability of the
bacterial samples exposed to the preparation. The growth of colonies of the bacterial
phytopathogen was counted after 72 hours. The bactericidal effect of the preparations was
judged by the presence or absence of growth on the fourth day on the solid medium. The tests
were carried out in duplicate.
2.4.2. The assessment of the biological activity of magnetic iron oxide nanoparticles and their
effect on biological objects.
The study of the iron oxides magnetic nanoparticles biological activity consisted of
determining the influence of treating the number of vegetable and grain crops seeds on their
germination energy, germination rate (GOST 12038-84), as well as through the influence of
the treatment of seeds and foliar effects on the plants morphophysiological characteristics
during the vegetative period. In a number of experiments, the effect of the treatment of
phytotest objects seeds with synthesized substances on the plant’s resistance to damage by
major phytopathogenic microorganisms was evaluated.
The phytotest objects of research were seeds and / or vegetative plants of spring barley,
zoned in the Leningrad region, as well as cabbage crops: white cabbage variety Penca de Povoa
(k-2558, Portugal), cauliflower variety Hobart (k-874, UK); garden cress variety Azhur and a
number of varieties and hybrids of vegetable crops, more adapted to the controlled conditions
of intensive light culture, lettuce of Typhoon and cucumber hybrid F1 Neva. The crops seeds
were obtained from the collections of the N.I. Vavilov All-Russian Institute of Plant Genetic
Resources (VIR) and Russian seed breeding companies (JSC “Agricultural selection and
production enterprise” Sortsemovosch, Gavrish).
The assessment of the effect of synthesized magnetic nanoparticles of iron oxides on
plants was carried out at the Agrophysical Research Institute (St. Petersburg), in laboratory
conditions and on a special biopolygon under controlled conditions of intensive light culture,
as well as in VIR greenhouses.
Presowing seed treatment was carried out by mixing for 10 min via simple shaking the
seeds in containers with water (control), as well as with the mentioned above aqueous
suspensions with different contents of synthesized iron oxides from 0.00001 to 100 mg/L.
Suspensions were prepared using an ultrasonic bath. This technique was especially necessary
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for nanoparticles coated with oleic acid since they did not mix well with water. The seeds were
dried at room temperature in air and then at 30 °C for 60 minutes in an oven. Seed drying
regimes corresponded to those specified in GOST 12038. Treated seeds were stored at room
temperature before sowing. The repetition of the experiment was 400 seeds for each variant of
the experiment.
Foliar treatment with aqueous suspensions of iron oxides magnetic nanoparticles in
concentrations of 0.001–1 mg was carried out three times every 5 days after the previous for
each stage of 3-5 true leaves development in a series of experiments during the period of
vegetative growth of cucumber hybrid F1 the Neva and lettuce variety Typhoon seedlings. In
the control variant, the plants were treated with water.
2.4.2.1. The assessment for the effect of test crops seed treatment with synthesized substances
on plant resistance to damage by major phytopathogenic microorganisms.
White cabbage cultivar Penca de Povoa (k-2558, Portugal) was used as phytotest object.
Its seeds were pretreated with iron oxides magnetic nanoparticles aqueous suspensions in
various concentrations. The seeds were planted on a substrate infected with cabbage blackleg
pathogens - micromycetes Pyhtium debaryanum Hesse, Olpidium brassicae Wor., Phizoctonia
aderholdii Kolosh., Leptosphaeria maculans (Sowerby) P. Karst., Fusarium sp). Cabbage
seeds treated with the mentioned aqueous suspensions and sown in cassettes with autoclaved
non-contaminated soil served as background controls. Seeds treated with distilled water and
sown on non-contaminated soil served as a general control without contamination. The plants
were cultivated for 21 days in a growing chamber at a constant air temperature of 18 °C and
light day/night mode - 16h / 8h. At the end of the experiment, two indicators were taken into
account - the number of plants and the degree of damage on the VIR scale (1 - no damage, 3 -
mild symptoms, 5 - typical symptoms, 7 - severe symptoms, necrosis, 9 - lack of seedlings)
according to the VIR methodological instructions [36]. In this case, the weighted average defeat
score for the variants was calculated according to the formula: М=∑(a*b)/N, where ∑(a*b) is
the sum of the affected variants multiplied by the corresponding defeat score, N is the total
number of variants [36].
2.4.2.2 The evaluation of the biological activity of magnetic iron oxide nanoparticles.
Seeds of phytotest objects were germinated in Petri dishes 10 cm in diameter on filter
paper soaked in 10 ml of an aqueous solution of the test substance. In the control variants, the
seeds were germinated in distilled water. On the 3rd day, the energy of seed germination was
assessed; on the 7th day - their germination rate (GOST 12038–84) and the length of shoots
and roots of seedlings were also measured. The studies were carried out in accordance with the
rules of the International Seed Testing Association (ISTA) and generally accepted methods
[37, 38]. All experiments were repeated three times.
2.4.3. Methodology for conducting vegetation experiments.
In a series of vegetation experiments under controlled conditions on the biopolygon of
the Agrophysical Research Institute, the seedlings of cucumber or lettuce were cultivated in a
plant growing light equipment [39] with light blocks lifting along the vertical axis containing
light sources - gas-discharge mirrored sodium lamps DNaZ-400 (Reflux, Russia). Irradiation
in the useful area in the field of photosynthetically active radiation was 80–90 W/m2, the
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duration of the light period was 14 h. The air temperature was maintained within the range of
+22...+ 24° С during the day and +18...+20 °С at night, the relative humidity of the air - at the
level of 65–75%. Seedlings of phytotest objects were grown on a small-volume analog of soil
“Agrophyte” [40] with the Knop’s nutrient solution applied to it [41] via the drip irrigation
technique. The number of lettuce plants - 5 pieces/tray, cucumber - 1 piece/container,
replication - 20 plants per each variant of the experiment. After three consecutive foliar
treatments, carried out during the stages of 3-5 true leaves development, the harvesting of
plants was carried out at the beginning of 6th leaf development of cucumber and the beginning
of 10-11 leaf of lettuce. Vegetation experiments were carried out in duplicate. When
harvesting, the height of the plants, the number and size of leaves, the leaf area, the wet and
dry weight of the above-ground part of the plants, and the percentage of dry matter were taken
into account. The biochemical composition of plants, namely the content of chlorophyll and
carotenoid pigments in the leaves, as well as trace elements (iron, copper, manganese, and
zinc), was determined in the Testing Laboratory of the Agrophysical Research Institute. The
determinations were carried out in accordance with the requirements of modern regulatory
documents and generally accepted methods [42, 43].
Statistical data processing was carried out using Excel 2010 and Statistica 8 programs
(Stat-Soft, Inc., USA). The mean values of the studied indicators, confidence intervals, and
coefficients of variation were determined. The significance of differences between the options
was assessed using parametric statistics methods (Student’s t-test). Differences between the
options were considered significant at p ≤ 0.05.
3. Results and Discussion
3.1. Phase composition of nanopowders.
The results of the X-ray phase analysis are shown in Fig. 2. As can be seen from the X-
ray diffraction patterns, they are almost identical. Broad peaks characteristic of nanoparticles
is observed in all three variants.
Figure 2. X-ray diffraction patterns of magnetic nanopowders synthesized by techniques 1, 2, and 3.
X-ray phase analysis showed that all powders correspond in composition to magnetite
and/or maghemite and do not contain more than 5% impurities of any other phase (Fig. 2).
Both maghemite and magnetite share a common crystal lattice structure. Therefore, it was not
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possible to distinguish magnetite from maghemite based only on the analysis of the position of
the peaks in the diffractograms of nanopowders. However, a comparison of the unit cell
parameters makes it possible to distinguish magnetite from maghemite [31, 43–46]. This was
done in this study. The results of calculating the parameters of unit cells for the synthesized
iron oxides are given in Table 1, along with literature data and data for natural magnetite and
commercial magnetite nanopowders.
The obtained data indicate solid solutions of maghemite and magnetite were obtained
during the syntheses in all three variants. Indeed, if magnetite and maghemite are isostructural,
then the chemical formula of maghemite can be represented as Fe(3-1/3)O4, and the formula of
the solid solution as Fe(3-δ)O4, where δ ≤ 1/3 [31, 47]. Using the dependence of the parameter a
(the size of the unit cell of the crystal lattice) on the number of vacancies in the crystal structure,
it is possible to determine to which crystalline modification the resulting nanopowder is closer
(Fig. 3, Table 1). The straight-line equation has the form of y=0.1818x+7.8505. Substituting
the value of the parameter into this equation, we get the value of δ.
Based on the values of the crystal lattice parameters, it can be concluded that the
nanopowder precipitated from aqueous solutions of iron salts using ultrasonic action and
isolated from the mother liquor by magnetic separation (technique 1) is very close in phase
composition to maghemite. For nanopowders deposited with continuous bubbling with argon
and heating to 60 °C (techniques 2 and 3), the preparation methods of which are almost
identical and differed only in the presence or absence of oleic acid addition, and different
methods of precipitation separation from the mother liquor (magnetic separation or
decantation), it is possible to state that they correspond to the composition of the maghemite-
magnetite solid solution, but also nevertheless closer to maghemite. In this case, apparently,
the action of the inert gas argon prevented complete oxidation of iron to the trivalent state.
Figure 3. Dependence of the parameter a of the unit cell of the crystal lattice of iron oxides on the number of
vacancies (δ) in the structure of the solid solution. The line is drawn according to the data of Nasrazadani &
Raman [41].
Table 1. Unit cell parameters for nanopowders obtained by techniques 1, 2, and 3, in comparison with
experimental data for natural and commercial magnetite and literature data.
Name a, Å
Maghemite γ-Fe2O3 [37, 39]] 8.336–8.339
Nanopowder, synthesized
via technique 1
8.3410.004
via techniques 2 and 3 (with oleic acid) 8.3550.004
Mineral magnetite*
Commercial magnetite *
Magnetite Fe3O4 [39, 42]
8.38400.0003
8.38550.0002
8.396–8.397 */The data were obtained by the authors for natural magnetite (Kovdorskoe deposit, Kola Peninsula, Russia) and commercial magnetite
(Sigma-Aldrich, CAS N 1317-61-9).
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The presence of oleic acid on the surface of iron oxide nanoparticles obtained by
technique 3 was confirmed by IR spectroscopy data (Fig. 4). The spectrum of sample 3 contains
absorption bands that correspond to the functional groups of oleic acid [48, 49].
Figure 4. IR spectra of nanopowders obtained via techniques 1 and 2 (without oleic acid) and 3 (with oleic
acid).
The bands at 2927 and 2852 cm-1 correspond to vibrations of the CH2 group
(asymmetric and symmetric vibrations, respectively), the band at 1706 cm-1 to the vibrations
of C = O, and the band at 1409 cm-1 to the vibrations of the CH3 group.
It is known [50-55] that maghemite is characterized by bands at 559 and 632 cm-1, and
magnetite - at 580 cm-1. Thus, we can conclude that in both cases, we are dealing with solid
solutions of iron oxides maghemite and magnetite. However, the sample obtained by technique
1 is closest in phase composition to maghemite since the size of the elementary parameter, a
crystal lattice, is very close to the parameters of maghemite.
In what follows, for the convenience of presenting the results of the powder
nanoparticles synthesized by technique 1 study, we will identify as maghemite and denote it as
γ-Fe2O3, and powder nanoparticles synthesized by methods 2 and 3 as nanoparticles
corresponding in composition to the maghemite-magnetite solid solution γ-Fe2O3-Fe3O4
without a shell and with a shell of oleic acid: γ-Fe2O3-Fe3O4@oleic acid.
3.2. Morphology of nanoparticles of powders.
SEM images of the surface of powder nanoparticles are shown in Fig. 5. These images
do not give a complete picture of the size and shape of powder nanoparticles. However, already
being guided by them, it can be concluded that nanoparticles in powders are agglomerated
regardless of the preparation technique.
To better assess the morphology and size of nanoparticles, they were examined using
high-resolution transmission microscopy (Fig. 6).
As can be seen from Fig. 6, nanoparticles of the γ-Fe2O3 powder obtained under
ultrasonic action in the absence of oleic acid and isolated from the mother liquor by means of
magnetic separation (technique 1) turned out to be larger, with a spread in size from 5-10 to 20
and even up to ~ 40 nm; they have a shape close to spherical. In contrast to them, nanoparticles
of γ-Fe2O3-Fe3O4 and γ-Fe2O3-Fe3O4@oleic acid powders were obtained by bubbling with
argon with heating (60 °C), regardless of how they were isolated from the mother liquor
(techniques 2 and 3) turned out to be smaller in size - from 5 to 20 nm. An increase in the size
of nanoparticles obtained by technique 3 (with oleic acid) in comparison with nanoparticles
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obtained by identical technique 2 (without oleic acid) occurs due to the shell of oleic acid,
which is clearly visible on Fig. 6 (2).
Figure 5. SEM image of the surface morphology of nanoparticles of powders obtained by techniques 1 (γ-
Fe2O3), 2 (γ-Fe2O3-Fe3O4), and 3 (γ-Fe2O3-Fe3O4@oleic acid).
Figure 6. TEM images of iron oxide nanoparticles obtained:
- according to technique 1 - γ-Fe2O3, under ultrasonic action, with magnetic separation (1a, 1b);
- according to technique 2 - γ-Fe2O3-Fe3O4, at 60 °C and bubbled with Ar, with magnetic separation (2);
- and according to technique 3 - γ-Fe2O3-Fe3O4@oleic acid, at 60 °C and bubbled Ar, using oleic acid and the
decantation method (3a, 3b).
3
3
1 1
2 2
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It should be especially noted that large-sized lamellar nanoparticles tend to roll up into
tubes. This can be seen from the TEM images (Fig. 6, 3 b), as well as from the microdiffraction
pattern (Fig. 7 c). They are a two-dimensional thin object, lamellar, or rolled into a tube. This
is evidenced by the characteristic bows, which are formed as a result of the fact that the invisible
crystal planes become visible when tilted relative to the electron beam (Fig. 7c).
Figure 7. Microdiffraction patterns for nanopowders obtained by the following methods: 1 - γ-Fe2O3 (a); 2 - γ-
Fe2O3-Fe3O4 (b), and 3 - γ-Fe2O3-Fe3O4@oleic acid (c).
Polycrystalline nanopowders were obtained by all three methods as the diffraction
patterns show thin rings (Fig. 7). For the γ-Fe2O3 nanopowder obtained by technique 1, a
chaotic distribution of luminous points is observed (Fig. 7a); that is, the structure of this
nanopowder is less ordered. Thus, the deposition of nanoparticles with continuous bubbling
with argon and heating to 60 °C promotes the formation of nanoparticles with a more ordered
crystal structure.
Fig. 8a shows the complete nitrogen adsorption-desorption isotherms for iron oxide
nanopowders obtained via techniques 1, 2, and 3, respectively. These isotherms are
characterized by pronounced capillary-condensation hysteresis and belong to type IV
according to the IUPAC classification, corresponding to adsorption on mesoporous (containing
pores with a diameter of 2–50 nm) materials. However, as can be seen from this figure, the
shape of the hysteresis loops for nanopowders prepared by different methods differs
significantly.
Figure 8. Adsorption-desorption isotherms (a) and their corresponding pore size distributions dV(D) (b),
obtained from the analysis of desorption isotherms using the BJH model, for iron oxide nanopowders: (1) γ-
Fe2O3 – 1st technique; (2) γ-Fe2O3-Fe3O4 – 2nd technique; (3) γ-Fe2O3-Fe3O4@oleic acid – 3nd technique.
Thus, the hysteresis loop observed for γ-Fe2O3 obtained by technique 1 almost
completely corresponds to the classical type H1, which is characteristic of porous materials
containing cylindrical pores open on both sides with a rather narrow pore size distribution. In
this case, the fact that the closure of the adsorption and desorption branches occurs at the values
a c b
a b
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of the partial pressures P/P0, much higher than 0.3, clearly indicates the absence of micropores
in this sample.
In the case of nanopowders: γ-Fe2O3-Fe3O4 and γ-Fe2O3-Fe3O4@oleic acid, prepared
according to techniques 2 and 3, respectively, the shape of the hysteresis loops can be attributed
to the H3 type according to the IUPAC classification, which is usually associated with the
presence of slot-like pores characteristic for materials consisting of lamellar particles.
Moreover, in the case of γ-Fe2O3-Fe3O4@oleic acid nanopowder prepared by technique 3, the
collapse of the hysteresis loop occurs at partial pressures P/P0<0.3, which, in turn, indicates the
presence of a significant number of micropores in the sample.
Mathematical processing of the complete nitrogen adsorption-desorption isotherms
within the Barrett-Joyner-Halenda (BJH) model made it possible to obtain the pore size
distributions dV(D) shown in Fig. 8b. As can be seen from this figure, the form of the obtained
distributions dV(D) significantly depends on the procedure for synthesizing the samples. Thus,
for the γ-Fe2O3 nanopowder obtained by technique 1, there is a clearly pronounced lognormal
pore size distribution with a maximum in the mesopore region dp13nm. At the same time,
both micro- and macropores are practically absent in this sample. The pore size distribution
dV(D) for the γ-Fe2O3-Fe3O4 composite nanopowder prepared according to technique 2 also
has a lognormal form, but with a diffuse maximum shifted to the region of larger mesopores
dp24nm. There are no micropores in this sample (Fig. 8b), which is also evidenced by the
closure of the hysteresis loop of adsorption-desorption isotherms in the region of high partial
pressures. At the same time, for the composite γ-Fe2O3-Fe3O4@oleic acid nanopowder
prepared by technique 3, the pore size distribution has a bimodal form with the maxima dp12
and dp28 nm, respectively. Thus, the obtained distributions dV(D) (Fig. 8b) are in satisfactory
agreement with the conclusions drawn from the analysis of the shape of the total nitrogen
adsorption-desorption isotherms for both iron oxide powders (Fig. 8a).
Table 2. The morphology of nanoparticles of powders obtained by three methods.
Parameters 1st technique
γ-Fe2O3
2nd technique
γ-Fe2O3-Fe3O4
3nd technique γ-Fe2O3-Fe3O4@oleic
acid
SBET (m2/g) 92.0 4 51.7 1 75.0 11
VP/P0→0.99(cm3/g) 0.35 0.34 0.43
dP (nm) BJH (des) 13.4 24.2 1.9; 7.9
Pore and
nanoparticle type
- open cylindrical
mesopores with a
narrow size
distribution;
- close to spherical
nanoparticles.
- slit-like mesopores;
- lamellar nanoparticles.
- slit-like micro- and mesopores;
- lamellar nanoparticles.
Nanoparticle size,
nm d = ~5-20 (40) = ~5-20 = ~10-20
Note: SBET - specific surface area; VP/P0 → 0.99 - specific pore volume; dp - average pore diameter - parameters
determined from the analysis of complete nitrogen adsorption-desorption isotherms using the BET and BJH
models; d is the diameter for spherical nanoparticles or the size of lamellar nanoparticles (lamellar, determined
from TEM data).
The results of determining the texture parameters of the iron oxide nanopowder samples
obtained from the analysis of the complete nitrogen adsorption-desorption isotherms using the
Brunauer–Emmett–Teller (BET) and BJH models are given in Table 2. According to the data
obtained (see Table 2), γ-Fe2O3 nanopowder prepared under the ultrasonic treatment (technique
1) has the largest specific surface area (SBET = 92 m2/g) and specific pore volume (VP/P0 →
0.99 = 0.35 cm3/g). The γ-Fe2O3-Fe3O4 sample obtained with argon bubbling and slight heating
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(technique 2) has a slightly lower specific surface area (SBET = 52 m2/g and almost the same
specific pore volume (VP/P0 → 0.99 = 0.34 cm3/g). The use of oleic acid as a surfactant leads
to an increase in both the specific surface area (SBET = 75 m2/g) and the specific pore volume
(VP/P0 → 0.99 = 0.43 cm3/g) of γ-Fe2O3-Fe3O4@oleic acid nanopowder (technique 3)
compared with γ-Fe2O3-Fe3O4 nanopowder obtained under identical conditions (technique 2).
The bimodal pore distribution in this powder may be due to the fact that it contains
nanoparticles with a wide size distribution, both plate-like and rolled into a tube.
It should be noted separately that all three nanopowders obtained via the 1st, 2nd, and
3rd techniques have magnetic properties; they are attracted to the magnet. Powders γ-Fe2O3
and γ-Fe2O3–Fe3O4 were separated from the mother liquor by magnetic separation.
Measurement of the magnetic properties of γ-Fe2O3-Fe3O4@oleic acid powder using the NMR
method in a flowing liquid (nutation method) [56] showed that this composite nanopowder is
a soft magnetic material (saturation magnetization 20000 A/m, remanent magnetization 250
A/m, coercive force 370 A/m).
3.3. Aggregate stability of aqueous suspensions of iron oxide nanopowders.
Data on the change in the hydrodynamic diameter of iron oxide nanoparticles in
aqueous suspensions during storage, which indirectly characterize the aggregate stability of
these suspensions, is given in Table 3.
Table 3. Average value of the hydrodynamic diameter of iron oxide nanoparticles (D) was obtained by three
different techniques in the supernatant liquids of aqueous suspensions during their storage.
Soak period Average value of the hydrodynamic diameter of iron oxide nanoparticles prepared
according to different aqueous synthesis techniques, D, nm
1st variant
γ-Fe2O3
2nd variant
γ-Fe2O3-Fe3O4
3rd variant
γ-Fe2O3-Fe3O4@oleic acid
The supernatant of the initial suspension (0.1 g/L) after sonication (240 W, 40 kHz, 20 minutes) during storage
One week 620 155 220
One month 600 155 220
10-Fold diluted supernatant of the original suspension during storage
One week 600 145 180
One month 650 140 180
Four months − 130 180
As can be seen from the table, the size of the hydrodynamic diameter of γ-Fe2O3
nanoparticles without oleic acid is significantly larger (by 3 times) than for composite γ-Fe2O3-
Fe3O4 and γ-Fe2O3-Fe3O4 @ oleic acid nanoparticles, both with and without oleic acid. This
can be caused by the larger size of γ-Fe2O3 nanoparticles, their greater tendency to aggregation,
as well as the formation of a substantially thicker hydration shell (by a factor of 3 or more).
Perhaps this is due to the presence of open cylindrical pores and a more developed surface. It
can be noted that judging by the values of the hydrodynamic diameter, the size of iron oxide
nanoparticles obtained by all three methods remained unchanged in aqueous suspensions for a
rather long time - for 1 month, and for γ-Fe2O3-Fe3O4 and γ-Fe2O3-Fe3O4@oleic acid
nanoparticles - over 4 months.
The disadvantage of suspensions based on nanoparticles with oleic acid γ-Fe2O3-
Fe3O4@oleic acid is the difficulty of their preparation because the surface of the particles is
poorly wetted with water. This problem was solved only with the use of ultrasonic exposure.
Thus, regardless of the specific features of the water deposition technique, iron oxide
nanopowders corresponding to the phase composition of γ-Fe2O3-Fe3O4 solid solutions, both
with and without surfactant on the surface, form stable aqueous suspensions with hydrated
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nanoparticle sizes in the range of ~ 130-650 nm. This conclusion is especially important since
it is these hydrated nanoparticles that will subsequently interact with seeds or various parts of
vegetative plants.
3.4. Biological activity of magnetic iron oxide nanoparticles and their effect on phytotest
objects.
3.4.1. Fungicidal and bactericidal properties against fungal and bacterial phytopathogenic
microorganisms.
Comparative assessment for the growth characteristics of bacterial colonies
Xanthomonas campestris pv. campestris (Pammel) Dowson., strain 5212 - the causative agent
of cabbage vascular bacteriosis, as well as spore germination and mycelium growth, the
formation of colonies of fungus Cochliobolus sativus (S. Ito & Kurib.) Drechsler ex Dastur -
the causative agent of barley dark brown spot and root rot for 5 days indicate that studied
aqueous suspensions of γ-Fe2O3 nanoparticles (0.001; 0.01; 0.1; 1.0; 10.0, 100.0 mg/L), γ-
Fe2O3–Fe3O4 and γ-Fe2O3–Fe3O4@oleic acid nanoparticles (0.1; 1.0; 10.0; 100.0 mg/L) ), in
the tested concentrations, do not possess fungicidal and bactericidal properties. In all variants
of the experiment, the growth and development of pathogens did not differ from those in the
control variants without the tested substances.
3.4.2. The effect of test crops seed treatment with magnetic iron oxide nanoparticles on plant
resistance to damage by major phytopathogenic microorganisms.
The data obtained (Table 4) on the survival rate of white cabbage variety Penca de
Povoa (k-2558, Portugal) plants and the incidence of blackleg disease when grown on a
substrate infected with fungal phytopathogens of this disease, in a greenhouse complex,
indicate that a weak protective effect on the plant, providing a tendency to an increase in their
survival rate and a decrease in the damage score, is provided by aqueous suspensions of γ-
Fe2O3–Fe3O4 nanoparticles at concentrations of 0.1 and 10.0 mg/L with the most pronounced
positive effect at a lower suspension concentration; and γ-Fe2O3–Fe3O4@oleic acid
nanoparticles at a concentration of 1.0 mg/L, which only at the indicated concentration showed
a slightly more significant positive effect on plant stress resistance compared to that of a
suspension of γ-Fe2O3–Fe3O4 nanoparticles without oleic acid at a concentration of 1.0 mg/L.
In other variants of concentrations, the protective effect was not revealed.
It should be noted that aqueous suspensions of γ-Fe2O3 nanoparticles do not have a
protective effect on plants due to the suppression of the vital activity of the latter. This effect
is less pronounced at the lowest tested concentration of the γ-Fe2O3 nanoparticle suspension
(0.01 mg/L) and increases with its raising.
Thus, suspensions of nanoparticles containing ferric and bivalent iron oxides (γ-Fe2O3–
Fe3O4) were found to be more effective at low concentrations in increasing the resistance of
white cabbage variety Penca de Povoa (k-2558, Portugal) plants to phytopathogenic damage
compared to the suspensions of nanoparticles with ferric iron oxides (γ-Fe2O3), which did not
show a protective effect at the tested concentrations. The presence of the oleic acid shell on the
surface of iron oxides (γ-Fe2O3–Fe3O4@oleic acid) magnetic nanoparticles also mainly did not
have a significant positive effect on their phytoprotective ability under conditions of infection
with fungal pathogens that cause blackleg in cabbage crops.
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Table 4. Survival of white cabbage variety Penca de Povoa (k-2558, Portugal) plants and its susceptibility to
blackleg when grown from seeds treated with the studied substances in favorable concentrations for plants, in a
substrate infected with fungal pathogens of root rot
Seed treatment option %alive
plants
Weighted average
damage score
water is a sterile substrate (control) 100,00 1
0.1 mg/L γ-Fe2O3-Fe3O4 57.15 4
10.0 mg/L γ-Fe2O3-Fe3O4 45.72 5
1.0 mg/L γ-Fe2O3-Fe3O4-@oleic acid 45.72 5
1.0 mg/L γ-Fe2O3-Fe3O4 34.29 7
0.01 mg/L γ-Fe2O3 22.86 7
water 38,86 8
0.1 mg/L γ-Fe2O3 0.00 9
1.0 mg/L γ-Fe2O3 0.00 9
0.1 mg/L γ-Fe2O3-Fe3O4-@oleic acid 0.00 9
10.0 mg/L γ-Fe2O3 0.00 9
10.0 mg/L γ-Fe2O3-Fe3O4-@oleic acid 0.00 9
3.4.3. Influence of the iron oxides magnetic nanoparticles concentrations on plant germination
and morphometric characteristics.
A series of experiments revealed similarities and differences in the reaction of plants:
spring barley variety Leningradsky, white cabbage variety Penca de Povoa, k-2558 and
cauliflower variety Hobart, k-874, as well as watercress variety Azhur for presowing seed
treatment with aqueous suspensions of iron oxides magnetic nanoparticles in the concentration
range 0.00001 - 100.0 mg/L (Electronic supplementary information, Table 1-3).
Various plant sensitivity to the effect of γ-Fe2O3 nanoparticles in the tested
concentration ranges revealed (Electronic supplementary information, Table 1). Thus, the
watercress of the Azhur variety and the white cabbage of variety the Penca de Povoa at the
initial stages of germination turned out to be indifferent to the treatment of seeds with γ-Fe2O3
suspensions, judging by the absence of the change in the indices of their germination energy
and germination capacity. At the same time, cauliflower variety Hobart, k-874, and spring
barley variety Leningradskiy reacted to seed treatment with γ-Fe2O3 suspensions at
concentrations (0.001, 0.1, 1.0, 10) mg/L and (0.0001, 0.01, 100.0) mg/L, respectively, slowing
germination on the 3rd day. On the 7th day, the marked inhibiting effect was retained in
cauliflower in the variants of seed treatment with γ-Fe2O3 suspensions (0.1 mg/L), and in spring
barley - at 0.01 and 100.0 mg/L.
Differences in the direction of changes in the values of germination energy in different
crops after treatment of their seeds with a suspension of γ-Fe2O3–Fe3O4 nanoparticles relative
to those in control were manifested from a pronounced decrease in spring barley, a neutral
reaction - in white cabbage, and stimulation in the form of a trend or significant - in cauliflower.
(Electronic supplementary information, Table 2). Seed germination in all crops mainly did not
differ from that in control or was higher, as, for example, in spring barley in the variants of
seed treatment with suspensions of γ-Fe2O3–Fe3O4 nanoparticles at concentrations of 0.01, 1,
and 10 mg/L. An exception was the treatment of barley seeds with a suspension of γ-Fe2O3–
Fe3O4 nanoparticles at a maximum concentration of 100 mg/L, which showed an inhibitory
effect on this indicator.
The presence of the oleic acid shell on the surface of γ-Fe2O3–Fe3O4@oleic acid
nanoparticles, when treated with suspensions of Leningradskiy spring barley seeds at a
concentration of 0.0001 mg/L, did not affect the germination energy of seeds; at a concentration
of 0.01 mg/L it significantly contributed to an increase in this value (by 24%), and in other
concentrations (0.001; 0.1; 1.0; 10.0 and 100.0 mg/L), it mainly significantly or in the form of
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a tendency decreased its values relative to the control (Electronic supplementary information,
Table 3). Treatment for seeds of white cabbage variety Penca de Povoa or cauliflower variety
Hobart with the above-mentioned suspensions of γ-Fe2O3–Fe3O4@oleic acid nanoparticles
mainly did not cause significant differences in the germination energy values from those in
control, except for the treatment of cauliflower seeds at a concentration of 0,01 mg/L. All the
differences revealed at the initial stages of germinations were leveled out on the 7th day, and
in terms of germination, the experimental variants did not differ significantly from the control
ones in all three phyto test cultures. A pronounced tendency to stimulate the germination of
spring barley seeds in the variants of their treatment with suspensions of γ-Fe2O3–Fe3O4@oleic
acid at concentrations of 0.001 and 0.01 mg/L can be noted.
Judging by all the assessed growth and development indices of plant seedlings, the
treatment of their seeds with γ-Fe2O3 suspensions had no effect or contributed to a significant
increase or in the form of a weak tendency, by 3-15% in the length of the sprouts of garden
cress variety Azhur at concentrations of 0.0001, 0.001, 0.01, 0.1, 1.0 and 10.0 mg/L; spring
barley variety the Leningradskiy - in concentrations of 0.1 and 1.0 mg/L, white cabbage - in
concentrations of 0.00001, 0.0001, 0.01; 1.0¸ 10.0 and 100.0 mg/L. cauliflower - at a
concentration of 0.00001, 0.0001, 0.001, 0.01, 0.1 mg/L. At the same time, there is a weak or
pronounced stimulation of root growth in garden cress by 6-28% with an increase in the
manifestation of the effect in the variants of seed treatment with γ-Fe2O3 suspensions at low
concentrations (0.001 and 0.01 mg/L); in spring barley - in concentrations of 0.0001, 0.01 and
0.1 mg/L. It should be noted that there is a tendency towards a slowdown in root growth also
in variants with seed treatment with γ-Fe2O3 suspensions at concentrations: for barley - 0.001,
10 and 100 mg/L; for white cabbage - 0.01-100 mg/L; for cauliflower - 0.00001 - 1.0 mg/L.
Treatment of test cultures seeds with suspensions of γ-Fe2O3–Fe3O4 nanoparticles in a
wide range of concentrations also revealed differences in the response of plant cultures,
namely: in cabbage crops - mainly stimulation of growth characteristics of plants (increase in
the length of shoots and roots by 3-18%); while in spring barley - a significant (in the variant
with a concentration of 10 mg/L) or in the form of a weak trend - a decrease in the growth rates
of seedlings (by 5-14%).
It was revealed that the presence of oleic acid shell on the surface of γ-Fe2O3–
Fe3O4@oleic acid nanoparticles contributed to an increase (up to 34%) in the absolute values
of growth indicators of barley seedlings when compared with those in the variants with seed
treatment with suspensions of γ-Fe2O3–Fe3O4 nanoparticles without oleic acid or γ-Fe2O3. At
the same time, the treatment of white cabbage seeds with suspensions of γ-Fe2O3–Fe3O4@oleic
acid nanoparticles did not affect the growth of sprouts but somewhat inhibited the growth of
roots. The effect of seed treatment with γ-Fe2O3–Fe3O4@oleic acid suspensions on root growth,
similar to the latter, was observed in cauliflower. However, in relation to sprouts, in contrast to
that observed in white cabbage, stimulation of their growth (by 8-15%) was revealed at low
concentrations of γ-Fe2O3–Fe3O4 nanoparticles (0.0001, 0.001, 0.01 mg/L).
In general, judging by all the assessed growth and development indices of plant
seedlings, the treatment of various plant species seeds with aqueous suspensions of γ-Fe2O3,
γ-Fe2O3–Fe3O4, and γ-Fe2O3–Fe3O4@oleic acid have a weak positive effect on plants in the
concentration range 0.00001 – 1 mg/L. The severity of the effect depends on the composition
and concentration of the tested substance and is determined by the specific characteristics of
the plant reaction. Thus, iron oxide nanoparticles in lower concentrations had a more significant
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positive effect on cabbage crops (white cabbage and cauliflower) relative to controls; no
significant effect on the growth characteristics of nanoparticles was found on spring barley.
All the revealed differences in germination energy at the initial stages of plant
development were leveled out on the 7th day, and in terms of germination, the experimental
variants did not significantly differ from the control ones in all three phyto test cultures.
3.4.4. Determination of the ranges of created compounds concentrations with positive influence
under vegetative plants foliar treatment.
Based on the results obtained on the treatment of plant seeds, a range of concentrations
of aqueous suspensions of γ-Fe2O3 and γ-Fe2O3–Fe3O4@oleic acid nanoparticles were selected
- 0.001-1.0 mg/L for foliar treatment of cucumber and lettuce seedlings.
The results of studies of the effect of magnetic nanoparticles obtained by 2 techniques
(1st and 3rd) on the morphophysiological characteristics of plants of the hybrid Neva F1
cucumber are shown in Fig. 9. It can be seen that practically all the assessed indicators of the
physiological state of plants (height, number of leaves, moisture content of plant material, raw
ash, and the above-mentioned weight of the above-ground part) have higher values compared
to the control.
Figure 9. Morphophysiological parameters of cucumber plants after foliar treatment with aqueous suspensions
of magnetic nanoparticles of iron oxides γ-Fe2O3 and γ-Fe2O3-Fe3O4@oleic acid in various concentrations when
growing plants under controlled conditions of intensive light culture.
Similar studies using only γ-Fe2O3 nanoparticles were repeated for two crops - a hybrid
of cucumber Neva F1 and lettuce variety Typhoon (Electronic supplementary information,
Tables 4 & 5).
It was found that aqueous suspensions of γ-Fe2O3 nanopowder at the tested
concentrations of 0.001-1.0 mg/L had a pronounced or weak tendency of stimulating effect on
plant growth indicators under foliar treatment of the cucumber and lettuce plants during
vegetative development (Electronic supplementary information, Table 4).
As our studies have shown, the stimulation of the cucumber and lettuce plants growth
under the influence of the synthesized magnetic iron oxide nanopowder is mainly due to: (a)
an increase in the intake of mineral nutrients, including zinc, manganese, into the above-ground
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part of the treated plants, which can be judged by a significant increase in the content raw plant
ash and the content of these elements (Electronic supplementary information, Table 5); (b) a
pronounced tendency to an increase in the water content of the tissues of stems and leaves after
treatment with suspensions of iron oxide, which in turn indirectly indicates a higher osmotic
potential in them due to the accumulation of low molecular weight compounds; to study the
noted effect, it is planned to carry out further experiments on the effect of magnetic iron oxide
nanoparticles suspensions under soil drought conditions on the stress resistance of plants; (c)
an increase in the area of the assimilating leaf surface and the content of chlorophylls in plant
leaves. The latter is more pronounced in the variants with the plants treated with γ-Fe2O3
suspensions at concentrations of 0.01 and 0.001 mg/L (Electronic supplementary information,
Table 5). In variants with a higher concentration, the content of chlorophylls in the leaves does
not differ from that in control. It should be noted that there are differences in the direction of
changes in the carotenoids content in cucumber and lettuce plants after treatment with
suspensions of iron oxide at various concentrations. Thus, in cucumber leaves, it is similar to
that in chlorophylls with maximum values when exposed to γ-Fe2O3 nanoparticles in low
concentrations and their decrease at concentrations of 0.1 and 1.0 mg/L, although more
significant relative to the control (by 18%). In lettuce leaves, under the influence of treatment
with γ-Fe2O3 suspensions, a significant or tendency reduction in the content of carotenoids by
13-28% is noted in the entire range of tested concentrations. It is well known that chlorophylls
a and b, carotenoids are pigments involved in photosynthesis and / or redox processes, and the
trace element iron catalyzes the formation of chlorophyll a pigment precursors - aminolevulinic
acid and protoporphyrins. In addition, iron compounds are involved in the formation of
chloroplast components: cytochromes, ferredoxin, etc. Apparently, with an increase in the
concentration of suspensions of iron nanoparticles during plant foliar treatment, the need for
the synthesis of secondary metabolites, including a number of pigments that enhance the
absorption of this microelement by the root system, decreases. The revealed phenomenon
requires additional in-depth research.
The revealed pronounced positive effect of foliar treatment with aqueous suspensions
of nanoparticles on the cucumber plants rates (F1 Neva hybrid) growth, the processes of the
biosynthesis of photosynthetic pigments in the leaves, the enrichment of nutrients in the above-
ground part of plants in the complex, obviously, provided the manifestation of a weak tendency
of plants productivity increase in variants treatment of plants with nanoparticles at a
concentration of 0.01 mg/L (Table 5).
Thus, the observed stimulation of the cucumber and lettuce seedlings growth after foliar
treatment with aqueous suspensions of magnetic iron oxide nanopowder (maghemite) is mainly
due to the intensification of metabolic processes and the supply of nutrients necessary for plants
to the above-ground part.
Table 5. Influence of foliar treatment with suspensions of iron oxide nanoparticles (concentration 0.01 mg/L) on
the productivity of cucumber plants (for example, F1 Neva hybrid) when grown under controlled conditions of
intensive light culture.
Foliage Reagents Number of fruits Weight of one fruit Yield, kg of fruits per m2
amount % of control g % of control kg % of control
Water (control) 12.5±1.2 100 19.0±4.7 100 19.4±1.9 100
γ-Fe2O3 13.0±2.5 104 19.5±8.7 99 20.0±2.7 103
γ-Fe2O3-Fe3O4 13.0±0.7 104 18.5±1.2 98 19.7±1.6 102
γ-Fe2O3-Fe3O4@oleic acid 13.5±1.2 108 202.5±8.5 104 21.9±3.6 113
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An increase in nutrition and an increase in the content of mineral elements in plants
contribute to an increase in the osmotic potential and, as a consequence, the hydration of tissues
due to the flow of water into cells with increased osmotic potential. This is a very positive fact,
which may indicate the ability of magnetic iron oxide nanoparticles to increase the plant's
resistance in drought conditions. It is obvious that iron, as a cofactor of many enzymes, is
involved in many metabolic processes in plants. Therefore, further study of the mechanisms of
the influence of magnetic nanoparticles of iron oxides of various crystalline modifications is
of great interest. The data obtained indicate that further studies of the mechanisms of the
influence of magnetic nanoparticles of iron oxides on plants under favorable and stressful
conditions are promising in order to create highly effective nano preparation and technology
for their use in crop production of an open and protected ground, aimed at increasing the
resistance of plants to stress factors and increasing the efficiency of their production potential.
4. Conclusions
Three variants of magnetic nanoparticles of iron oxides, differing in phase composition,
shape, and texture, were obtained by chemical deposition from aqueous solutions of iron (II,
III) chlorides. The synthesis procedure was distinguished by the fact that according to the 1st
technique, ultrasonication was used, according to the 2nd technique - bubbling with argon and
heating to 60 °C during deposition, according to the 3rd technique, the synthesis was carried
out similar to the second variant. Additionally, oleic acid was introduced into the reaction
mixture. The mixture was subjected to homogenization at 50 °C and separated from the mother
liquor not by magnetic separation (as in the first two variants), but by decantation. As a result,
nanoparticles obtained under ultrasonication at room temperature most closely correspond in
phase composition to maghemite (γ-Fe2O3), the shape of them is close to spherical and size
within 5-20 (up to ~ 40 nm), with a specific surface area of ~ 92 m2/g. According to the second
and third techniques of synthesis, with bubbling with argon and slight heating (60 °C),
regardless of the method of isolation from the mother liquor and the presence or absence of a
shell of oleic acid, identical in phase composition lamellar nanoparticles were obtained, which
corresponds to a solid solution of maghemite-magnetite γ-Fe2O3-Fe3O4. Thus, according to the
second and third techniques, nanoparticles of iron oxides with a higher content of ferrous iron
were obtained in comparison with the nanoparticles obtained by the first method. As a result
of the introduction of oleic acid into the reaction mixture, a film was formed on the surface of
the nanoparticles, and composite γ-Fe2O3-Fe3O4@oleic acid nanoparticles were formed. This
somewhat increased both the size of nanoparticles (from ~ 5-20 nm to ~ 10-20 and even up to
~ 40 nm) and the specific surface area (from ~ 52 to 75 m2/g). At the same time, individual
composite lamellar nanoparticles tended to roll up into tubes. After reaching sedimentation
stability, aqueous suspensions of all three variants of nanoparticles retained their aggregate
stability for more than 1 month at an aggregate size of ~ 550 nm (for γ-Fe2O3) and for more
than 4 months at an aggregate size of ~ 130 nm (for γ-Fe2O3-Fe3O4) and ~ 180 nm (for γ-Fe2O3-
Fe3O4@oleic acid).
The studied aqueous suspensions of γ-Fe2O3 nanoparticles (0.001; 0.01; 0.1; 1.0; 10.0,
100.0 mg/L), and γ-Fe2O3-Fe3O4 and γ-Fe2O3-Fe3O4@oleic acid nanoparticles (0.1; 1.0; 10.0;
100.0 mg/L), in the tested concentrations do not possess fungicidal and bactericidal properties
in relation to phytopathogens – the causative agent of dark brown spot and root rot of barley -
the micromycete Cochliobolus sativus (S. Ito & Kurib.) and the causative agent of vascular
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bacteriosis of cabbage – Xanthomonas campestris pv. campestris (Pammel) Dowson,
respectively.
Aqueous suspensions of magnetic nanoparticles corresponding to the composition of
the γ-Fe2O3–Fe3O4 solid solution, containing oxides of ferric and ferrous iron, were found to
be more effective at low concentrations in increasing the resistance of white cabbage cultivar
Penca de Povoa (k-2558, Portugal) plants to fungal pathogens causing blackleg in cabbage
crops, compared with suspensions of nanoparticles that most closely correspond to the
composition of maghemite (γ-Fe2O3), which did not show a protective effect at the tested
concentrations. The presence of a shell of oleic acid on the surface of magnetic nanoparticles
of iron oxides (γ-Fe2O3–Fe3O4) also predominantly did not have a significant positive effect on
their phytoprotective ability in conditions of infection with phytopathogens causing blackleg
disease. On the contrary, smaller, also lamellar nanoparticles ~ 5-20 nm in size, corresponding
to the composition of the γ-Fe2O3–Fe3O4 solid solution, without oleic acid, exhibited higher
protective properties. In the future, it is of interest to find out what affects to a greater extent
the bactericidal properties of nanoparticles - their size or phase composition (Fe atoms in
oxidation state II or III).
In general, judging by all the assessed growth and development indices of plant
seedlings, the treatment of seeds of various plant species with aqueous suspensions of γ-Fe2O3,
γ-Fe2O3–Fe3O4, and γ-Fe2O3–Fe3O4@oleic acid nanoparticles have a weak positive effect on
plants in the concentration range 0.00001-1 mg/L. The severity of the effect depends on the
composition and concentration of the tested substance and is determined by the specific
characteristics of the plant reaction. Thus, iron oxide nanoparticles in lower concentrations had
a more significant positive effect on cabbage crops (white cabbage and cauliflower) relative to
the control. No significant effect on the growth characteristics of spring barley was found. All
the revealed differences in germination energy at the initial stages of plant development were
leveled significantly from the control in all three phyto test cultures. The stimulation of the
growth of seedlings of cucumber and lettuce after foliar treatment with aqueous suspensions of
magnetic γ-Fe2O3 nanoparticles, revealed in a series of vegetation experiments under controlled
conditions of intensive light culture, is mainly due to an increase in metabolic processes and
the supply of nutrients necessary for plants to the above-ground part. An increase in nutrition
and an increase in the content of mineral elements in plants contributes to an increase in the
osmotic potential and, as a consequence, tissue hydration due to the flow of water into cells
with increased osmotic potential. This is a very positive fact, which may indicate the ability of
magnetic iron oxide nanoparticles to increase the resistance of plants in drought conditions. It
is obvious that iron, as a cofactor of many enzymes, is involved in many metabolic processes
in plants. Therefore, further study of the mechanisms of the influence of magnetic nanoparticles
of iron oxides in various crystalline modifications is of great interest. The data obtained indicate
that further studies of the mechanisms of the influence of magnetic nanoparticles of iron oxides
on plants under favorable and stressful conditions are promising in order to create highly
effective nano preparation and technology for their use in crop production of open and
protected ground, aimed at increasing the resistance of plants to stress factors and increasing
the efficiency of their production potential.
In general, the phase composition and size of nanoparticles obtained by all three
methods are close. However, even a small shift towards an increase in the number of ferrous
iron atoms in the phase composition of nanoparticles had a positive effect after seed treatment
on the resistance of white cabbage cultivar Penca de Povoa to blackleg disease when plants
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were grown in a substrate infected with fungal root rot pathogens. The influence of the size,
shape, and phase composition of magnetic iron oxide nanoparticles on the morphometric and
biochemical parameters of plants, both during pre-sowing seed treatment and when processing
vegetative plants with nanoparticles, is less obvious. However, the positive effect of oleic acid,
oddly enough, is manifested in the fact that the best results in almost all parameters are achieved
at lower concentrations of nanoparticles. All three variants of nanoparticles had a positive
effect on the yield of cucumbers when used for foliar treatment of plants. It is interesting to
note that it is the composite nanoparticles corresponding to the composition of the maghemite-
magnetite solid solution with a shell of oleic acid that contributed to the highest productivity
of cucumber plants. In the future, to enhance the phytoprotective effect, it is planned to test the
effect of modifying the surface of iron oxide nanoparticles with various substances, such as
silicon dioxide or carbon nanomaterials, which, if successful, will reduce the dose load of
persistent agrochemicals and pesticides on the environment.
Funding
The present work was supported by the Russian Scientific Foundation, project №19-13-00442.
Acknowledgments
This research has no acknowledgment.
Conflicts of Interest
The authors declare no conflict of interest.
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